The stiffened deep cement mixing (SDCM) pile is a composite pile composed of the deep cement mixing (DCM) pile and an inner precast core pile. The excellent bearing performance of the SDCM pile that has been successfully witnessed in engineering practice is attributed to the double-layer load transfer mechanism, which effectively transfer the load from the stiffened core to the cemented soil and further to the adjacent soil. The mechanical properties of SDCM piles with stiffened cores that using large-size prestressed high-strength concrete (PHC) piles are rarely studied. This study aims to explore the bearing performance and failure behavior of the SDCM pile with a large-size PHC pile as stiffened core. The relationship between load and settlement as well as the distribution and development of axial force and lateral resistance was studied through field full-scale tests. The effects of the volume ratio, size, and concrete stiffness of the core pile, and the strength of cemented soil on the axial bearing capacity of SDCM piles were explored through the verified three-dimensional numerical model. The load transfer and failure modes at the internal and external interfaces of SDCM piles with different pile lengths were analyzed. Results show that the length of the core pile (Lcore) is a key factor for the bearing capacity of the SDCM pile. The bearing capacity of SDCM pile increases by 57.90% and 46.67% with Lcore increasing by 45% when cemented soil strength (qu, DCM) is 150 MPa and 300 MPa, respectively. The influence of qu, DCM and concrete stiffness on the bearing capacity of the SDCM pile is gradually significant with the increase of Lcore. The ultimate bearing capacity increases by 4.3% for every 100% increase in cemented soil strength at the optimal pile length. With the increase of Lcore, the investigated pile exhibits three failure modes, including the failure of pile end soil and cemented soil, the failure of pile top soil and core pile end soil, and the failure of pile top soil. The results of this study provide reference for the application of SDCM piles with large-size PHC piles as stiffened cores in the engineering field.

Investigations on the changes in pore water pressures and stress during the construction of stiffened deep cement mixing (SDCM) piles are scarce, resulting in an unsatisfactory understanding of the bearing capacity formation process. Thus, this paper presents a preliminary field study to investigate the variation characteristics of pore water pressures, total stress and effective stress during the construction of SDCM piles derived from field tests. In the meantime, cone penetration tests (CPTs) were conducted before and after the construction of SDCM piles. The results show that the variation ranges of pore water pressure, total stress and effective stress of soils around piles decreased with increasing distance between the measuring point and piles when the depths of the measuring points were the same. During the piling process, the effective stress increased by approximately 53-103%, and the pile side frictions increased accordingly, while the tip resistance and side resistance values of soils around piles increased by 27-106% and 2-145%, respectively. Additionally, SDCM piles successively formed different load-bearing components with decreasing bearing capacity along the pile diameter direction, which realized a better bearing efficiency than conventional piles made with homogeneous materials. In essence, they were also the source of significant economic advantages of SDCM piles. Through this study, we expect to provide a reference for further studies on the bearing mechanism of SDCM piles in soft soil regions.